Storage apparatus and controlling method of storage apparatus

ABSTRACT

A storage apparatus including: a first controller that generates an access to a storage device; the first controller includes: a first relay unit configured to relay the access to the storage device; and an access control unit configured to be activated after activation of the first relay unit and to relay the access to the storage device via a second relay unit; and a second controller that includes the second relay unit and generates the access to the storage device, wherein when the first relay unit receives a connection request for an access path between the first relay unit and the storage device from the second controller, the first relay unit establishes the access path to the storage device irrespective of an activation state of the access control unit.

CROSS-REFERENCE TO RELATED APPLICATION

This application is based upon and claims the benefit of priority of the prior Japanese Patent Application No. 2011-61386, filed on Mar. 18, 2011, the entire contents of which are incorporated herein by reference.

FIELD

The embodiments discussed herein are related to a storage apparatus and a controlling method of a storage apparatus.

BACKGROUND

In recent years, there is widespread use of storage apparatuses including a plurality of mass storage devices such as Hard Disk Drives (HDDs). A storage system typically includes a plurality of storage devices, and a controller that controls access to these storage devices. There are also storage systems in which a plurality of controllers are provided to allow redundancy in the access paths to the storage devices. By providing redundancy in the access paths, the reliability of access to the storage devices may be improved.

Further, redundancy may be provided in the access path between each controller and the storage device by providing each controller with a second access path that goes through another controller between the controller and the storage device, in addition to a first access path that directly connects the controller and the storage device. For example, a conceivable configuration is such that in a case where each controller includes an expander that relays access to the storage device, each controller makes access to the storage device by using an access path through which the controller accesses the storage device via the expander within the controller itself, and an access path through which the controller accesses the storage device via an expander included in another controller.

In a case where each controller is configured such that its expander is activated with activation of a control unit that controls storage of data in the storage device, if the control unit in one controller is not activated due to some reason, it is no longer possible to access the storage device by using an access path that uses an expander connected to the control unit that is not activated.

Examples of related art are discussed in Japanese Laid-open Patent Publications Nos. 2006-155392, 2006-72636, 59-070145, and 2003-44178.

SUMMARY

According to an aspect of the invention, a storage apparatus including: a first controller that generates an access to a storage device; the first controller includes: a first relay unit configured to relay the access to the storage device; and an access control unit configured to be activated after activation of the first relay unit and to relay the access to the storage device via a second relay unit; and a second controller that includes the second relay unit and generates the access to the storage device, wherein when the first relay unit receives a connection request for an access path between the first relay unit and the storage device from the second controller, the first relay unit establishes the access path to the storage device irrespective of an activation state of the access control unit.

The object and advantages of the invention will be realized and attained by means of the elements and combinations particularly pointed out in the claims. It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not restrictive of the invention, as claimed.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 illustrates a storage apparatus according to a first embodiment;

FIG. 2 illustrates a general configuration example of a storage system according to a second embodiment;

FIG. 3 illustrates a hardware configuration example of controller modules;

FIG. 4 illustrates a hardware configuration example of a management terminal apparatus;

FIG. 5 is a block diagram illustrating an example of processing functions included in controller modules;

FIG. 6 is a block diagram illustrating the functions of expanders; and

FIG. 7 is a method illustrating processing in expanders.

DESCRIPTION OF EMBODIMENTS

Hereinafter, a storage apparatus according to the embodiments is described in detail with reference to the drawings. An embodiment of a storage apparatus is described with reference to a first embodiment, and then the storage apparatus is described more specifically with reference to a second embodiment.

First Embodiment

FIG. 1 illustrates a storage apparatus according to a first embodiment.

A storage apparatus 1 according to the first embodiment has a first controller 4 and a second controller 5 that each accesses a storage device 3 upon instruction from a host apparatus 2. While the storage apparatus 1 in FIG. 1 has two controllers, the first controller 4 and the second controller 5, the storage apparatus 1 may have three or more controllers.

The storage device 3 is a device that stores data. For example, the storage device 3 has a plurality of internal storage media such as HDDs. The first controller 4 and the second controller 5 each control access to the storage device 3. The first controller 4 and the second controller 5 each make access to the storage device 3 in response to an access request for the storage device 3 from the host apparatus 2.

For example, upon accepting a request for reading data stored in the storage device 3 from the host apparatus 2, the first controller 4 and the second controller 5 each read the requested data from the storage device 2, and transmit the read data to the host apparatus 2. Also, upon accepting a request for writing data to the storage device 3 from the host apparatus 2, the first controller 4 and the second controller 5 each write the requested data to the storage device 3. The first controller 4 and the second controller 5 may include the function of caching data stored in the storage device 3.

The first controller 4 and the second controller 5 have the same configuration. The first controller 4 includes an access control unit 4 a and a first relay unit 4 b. The second controller 5 includes an access control unit 5 a and a second relay unit 5 b. The access control unit 4 a and the access control unit 5 a, and the first relay unit 4 b and the second relay unit 5 b may each execute the same processing.

The access control unit 4 a accesses the storage device 3 via the first relay unit 4 b or the second relay unit 5 b. The access control unit 5 a accesses the storage device 3 via the second relay unit 5 b or the first relay unit 4 b.

The first relay unit 4 b relays access from the access control unit 4 a to the storage device 3, and also relays access from the access control unit 5 a to the storage device 3. The second relay unit 5 b relays access from the access control unit 5 a to the storage device 3, and also relays access from the access control unit 4 a to the storage device 3.

In this way, by providing redundancy in each of the access path from the access control unit 4 a to the storage device 3, and the access path from the access control unit 5 a to the storage device 3, the reliability of access from the host apparatus 2 to the storage device 3 improves.

An electrical supply unit 6 supplies power from a control power source to each of the first controller 4 and the second controller 5. The electrical supply unit 6 may be configured with redundancy. For example, when activating the first controller 4, power from a control power source is supplied to the first relay unit 4 b from the electrical supply unit 6. With the supply of power, the first relay unit 4 b is activated prior to activation of the access control unit 4 a. The first relay unit 4 b permits supply of power from the electrical supply unit 6 to the access control unit 4 a. This permission enables activation of the access control unit 4 a. When the access control unit 4 a is activated, the access control unit 4 a establishes connection with the first relay unit 4 b.

The first relay unit 4 b may start monitoring for a fault in the first controller 4 after being activated. Examples of the kinds of fault include, for example, a temperature fault (e.g. overheating), a current fault (e.g. over-current), and a voltage fault (e.g. over-voltage). If no fault is present as a result of monitoring, the first relay unit 4 b may permit supply of power from the electrical supply unit 6 to the access control unit 4 a. If a fault is present as a result of monitoring, the first relay unit 4 b does not permit supply of power from the electrical supply unit 6 to the access control unit 4 a. Consequently, the access control unit 4 a is not activated. The first control unit 4 b may determine whether or not to permit supply of power from the electrical supply unit 6 to the access control unit 4 a depending on the kind of the fault. Also, the first control unit 4 b may stop activation of the first relay unit 4 b depending on the kind of the fault. FIG. 1 illustrates, as an example, a case where the first relay unit 4 b does not permit supply of power from the electrical supply unit 6 to the access control unit 4 a, and the access control unit 4 a is not activated. At this time, when the first relay unit 4 b receives a connection request for the access path between the first relay unit 4 b and the storage device 3 from the second controller 5, the first relay unit 4 b establishes the access path to the storage device 3, irrespective of the activation state of the access control unit 4 a. Therefore, in a state in which the access control unit 5 a is activated, and the second relay unit 5 b has established an access path to the storage device 3, the access control unit 5 a is able to access the storage device 3 via the second relay unit 5 b or the first relay unit 4 b. Therefore, the host apparatus 2 may ensure a redundant access path to the storage device 3.

After establishing the access path to the storage device 3, the first relay unit 4 b may notify the second relay unit 5 b of a connection request for connection to the storage device 3. With this notification, the second relay unit 5 b establishes an access path to the storage device 3 irrespective of the state of the access control unit 4 a. Therefore, in a state in which the access control unit 4 a is activated, and the first relay unit 4 b has established an access path to the storage device 3, the access control unit 4 a is able to access the storage device 3 via the first relay unit 4 b or the second relay unit 5 b. According to the storage apparatus 1, a redundant access path from the host apparatus 2 to the storage device 3 may be secured if either one of the access control units 4 a or 5 a is activated.

Second Embodiment

Next, a configuration example of a storage apparatus using expanders as relay units that relay access to storage devices is described. FIG. 2 illustrates a general configuration example of a storage system according to a second embodiment.

A storage system 1000 illustrated as FIG. 2 has a storage apparatus 100, a host apparatus 20, and a management terminal apparatus 30.

The storage apparatus 100 includes a plurality of HDDs. A plurality of HDDs are stored in each of Drive Enclosures (DEs) 210 and 220 in the storage apparatus 100. The DE 210, 220 may be provided outside of the storage apparatus 100, for example. Storage media included in the storage apparatus 100 are not limited to HDDs but may be, for example, other kinds of storage media such as Solid State Drives (SSDs). The storage apparatus 100 also includes two controller modules 10 a and 10 b that control access to a HDD in the DE 210, 220. The controller module 10 a is an example of the first controller, and the controller module 10 b is an example of the second controller.

The storage apparatus 100 is connected with the host apparatus 20 and the management terminal apparatus 30. The host apparatus 20 requests the controller module 10 a or the controller module 10 b in the storage apparatus 100 for access to a HDD in the DE 210 or a HDD in the DE 220, in accordance with manipulation by the user. The host apparatus 20 and the controller module 10 a, 10 b are connected via, for example, an optical fiber.

The management terminal apparatus 30 manages operation of the storage apparatus 100 in accordance with manipulation by the administrator. For example, in accordance with manipulation by the administrator, the management terminal apparatus 30 may request for turning-on or turning-off of the power to each of the controller modules 10 a and 10 b in the storage apparatus 100. The management terminal apparatus 30 and the controller module 10 a, 10 b are connected via, for example, a Local Area Network (LAN) cable.

The controller modules 10 a and 10 b each control access to a HDD in the DE 210, 220 upon access request from the host apparatus 20. For example, upon accepting a request for reading data stored in a HDD, the controller module 10 a, 10 b reads the requested data from the HDD, and transmits the read data to the host apparatus 20. Also, upon accepting a request for writing data to a HDD, the controller module 10 a, 10 b writes the requested data to the HDD.

The controller module 10 a, 10 b has the function of caching data stored in the HDDs in the DE 210, 220. The controller module 10 a and the controller module 10 b may transmit and receive data to and from each other. For example, the controller module 10 a, 10 b retains a backup of cached data retained by the other controller module 10 a, 10 b. The controller module 10 a, 10 b may also control the power-on state of the other controller module 10 a, 10 b. The controller module 10 a, 10 b may manage data stored in the HDDs in the DE 210, 220 by Redundant Arrays of Inexpensive Disks (RAID).

Power Supply Units (PSUs) 40 a and 40 b are provided in the storage apparatus 100. The PSU 40 a, 40 b is a power circuit that supplies power to the controller module 10 a, 10 b, and supplies drive power to the DE 210, 220.

FIG. 3 illustrates a hardware configuration example of the controller modules 10 a and 10 b.

The controller module 10 a includes a Central Processing Unit (CPU) 11 a, a Random Access Memory (RAM) 12 a, a Peripheral Component Interconnect (PCI) switch 13 a, Channel Adapters (CA) 14 a and 15 a, In/Out controllers (IOCs) 16 a and 17 a, expanders 18 a and 19 a, a Platform Controller Hub (PCH) 20 a, a SSD 21 a, a LAN interface 22 a, a Field Programmable Gate Array (FPGA) 23 a, and a Non Volatile RAM (NVRAM) 24 a. The expander 18 a is an example of the first relay unit.

The controller module 10 b is implemented in the same hardware configuration as that of the controller module 10 a. That is, a CPU 11 b, a RAM 12 b, a PCI switch 13 b, CAs 14 b and 15 b, IOCs 16 b and 17 b, expanders 18 b and 19 b, a PCH 20 b, a SSD 21 b, a LAN interface 22 b, a FPGA 23 b, and a NVRAM 24 b inside the controller module 10 b correspond to the CPU 11 a, the RAM 12 a, the PCI switch 13 a, the CAs 14 a and 15 a, the IOCs 16 a and 17 a, the expanders 18 a and 19 a, the PCH 20 a, the SSD 21 a, the LAN interface 22 a, the FPGA 23 a, and the NVRAM 24 a inside the controller module 10 a, respectively. The expander 18 b is an example of the second relay unit.

Hereinafter, basically the hardware configuration of the controller module 10 a is described, and a description of the hardware configuration of the controller module 10 b is omitted.

The CPU 11 a controls the entire controller module 10 a in a centralized manner. The RAM 12 a is used as the primary storage device of the controller module 10 a. The RAM 12 a temporarily stores at least part of programs to be executed by the CPU 11 a, and various kinds of data used for processing executed by the programs. The RAM 12 a is also used as a cache area for data stored in the HDDs in the DE 210, 220.

The PCI switch 13 a transmits and receives data between the CPU 11 a, the CA 14 a, 15 a, and the IOC 16 a, 17 a. The PCI switch 13 a is connected to the PCI switch 13 b in the other controller module 10 b. Hereinafter, the communication path between the PCI switch 13 a and the PCI switch 13 b is referred to as “communication path P1”.

The CPU 11 a of the controller module 10 a and the CPU lib of the controller module 10 b are able to communicate with each other via the communication path P1. For example, the CPU 11 a of the controller module 10 a may acquire fault detection information from the CPU 11 b of the controller module 10 b via the communication path P1. The fault detection information indicates the details of a fault that has occurred in the other controller module 10 b. Also, for example, the CPU 11 a may also transmit cached data of the HDDs stored in the RAM 12 a to the CPU 11 b of the other controller module 10 b via the communication path P1, and request the RAM 12 b in the other controller module 10 b to back up the cached data.

The CA 14 a, 15 a executes interfacing to transmit and receive data between the host apparatus 20 and the controller module 10 a. By connecting the CAs 14 a and 15 a to the host apparatus 20 individually by a separate optical fiber cable, redundancy is provided for the communication path between the controller module 10 a and the host apparatus 20, thereby further improving the reliability of communication.

The IOCs 16 a and 17 a are each a control circuit (SAS controller) that executes interfacing with the HDDs in the DE 210, 220 that is a SAS device. The expanders 18 a and 19 a each relay data between a SAS controller and a SAS device. The interface between the IOC 16 a, 17 a and the DE 210, 220 is not limited to SAS. The expanders 18 a and 19 a are able to communicate with each other via two paths including a path using a I²C bus interface and a path using a FPGA register (both not illustrated).

The expanders 18 a and 19 a each have an internal memory, and retain information indicative of the power-on state of the controller module 10 a (e.g. Not powered on yet, Being powered on, Power-on complete) in the internal memory.

The IOC 16 a is connected to the DE 210, 220 via the expander 18 a. Also, the IOC 16 a is connected to the DE 210, 220 via the expander 18 b in the controller module 10 b. Since the IOC 16 a and the DE 210, 220 are connected via the two expanders 18 a and 18 b in this way, redundancy is provided for the access path from the IOC 16 a to the DE 210, 220. The IOC 17 a is connected to the DE 210, 220 via the expander 19 a. Also, the IOC 17 a is connected to the DE 210, 220 via the expander 19 b in the controller module 10 b. Since the IOC 17 a and the DE 210, 220 are connected via the two expanders 19 a and 19 b, redundancy is provided for the access path from the IOC 17 a to the DE 210, 220.

Likewise, the IOC 16 b is connected to the DE 210, 220 via the expander 18 b. Also, the IOC 16 b is connected to the DE 210, 220 via the expander 18 a in the controller module 10 a. Since the IOC 16 b and the DE 210, 220 are connected via the two expanders 18 a and 18 b in this way, redundancy is provided for the access path from the IOC 16 b to the DE 210, 220. The IOC 17 b is connected to the DE 210, 220 via the expander 19 b. Also, the IOC 17 b is connected to the DE 210, 220 via the expander 19 a in the controller module 10 a. Since the IOC 17 b and the DE 210, 220 are connected via the two expanders 19 a and 19 b, redundancy is provided for the access path from the IOC 17 b to the DE 210, 220.

In the following description, the path through which the IOC 16 a accesses the DE 210, 220 via the expander 18 a, the path through which the IOC 17 a accesses the DE 210, 220 via the expander 19 a, the path through which the IOC 16 b accesses the DE 210, 220 via the expander 18 b, and the path through which the IOC 17 b accesses the DE 210, 220 via the expander 19 b are referred to as “straight paths”. Also, the path through which the IOC 16 a accesses the DE 210, 220 via the expander 18 b, the path through which the IOC 17 a accesses the DE 210, 220 via the expander 19 b, the path through which the IOC 16 b accesses the DE 210, 220 via the expander 18 a, and the path through which the IOC 17 b accesses the DE 210, 220 via the expander 19 a are referred to as “cross paths”.

The PCH 20 a transmits and receives data between the CPU 11 a, the SSD 21 a, the LAN interface 22 a, and the FPGA 23 a.

The SSD 21 a is used as the secondary storage device of the controller module 10 a. The SSD 21 a stores programs to be executed by the CPU 11 a, various kinds of data used for execution of the programs, and the like. As the secondary storage device, for example, other kinds of non-volatile storage devices such as a HDD may be used.

The LAN interface 22 a connects to the management terminal apparatus 30 via a LAN cable, and transmits and receives data to and from the management terminal apparatus 30.

When a fault during program execution is detected by the CPU 11 a, the FPGA 23 a receives fault detection information indicating the details of the detected fault from the CPU 11 a, and stores the received fault detection information into the NVRAM 24 a. Further, the FPGA 23 a includes the function of communicating with the FPGA 23 b of the controller module 10 b. Hereinafter, the communication path between the FPGA 23 a and the FPGA 23 b is referred to as “communication path P2”. The FPGA 23 a may also transmit the fault detection information stored in the NVRAM 23 a to the FPGA 23 b of the controller module 10 b via the communication path P2, upon request from the CPU 11 a or upon request from the FPGA 23 b of the controller module 10 b.

The processing executed by the FPGA 23 a may be executed by, for example, other kinds of control circuits such as a microcomputer.

The NVRAM 24 a is a non-volatile memory that stores various kinds of data used for processing in the FPGA 23 a. The NVRAM 24 a also stores information for identifying the connecting location of the expender 18 a, 19 a with respect to the CPU 11 a. Also, fault detection information indicating the details of a fault detected by the controller module 10 a is stored into the NVRAM 24 a by the FPGA 23 a.

In a case where power is supplied to the controller module 10 a from the PSU 40 a or the PSU 40 b in a state in which power is not being supplied to the controller module 10 a, the FPGA 23 a and NVRAM 24 a of the controller module 10 a are activated first. Then, the expander 18 a, 19 a is activated. Since the FPGA 23 a and the NVRAM 24 a have already been activated when the expander 18 a, 19 a is activated, it is possible to access the NVRAM 24 a from the expander 18 a, 19 a via the FPGA 23 a.

When activated, the expander 18 a, 19 a accesses a predetermined register in the NVRAM 24 a via the FPGA 23 a. The location of the register to be accessed differs between the expanders 18 a and 19 a. Then, by reading information stored in the register, the expander 18 a, 19 a is able to learn whether it is the expander 18 a or the expander 19 a.

FIG. 4 illustrates a hardware configuration example of the management terminal apparatus 30.

The entire management terminal apparatus 30 is controlled by a CPU 131. The CPU 131 is connected with a RAM 132 and a plurality of peripheral devices via a bus 138.

The RAM 132 is used as the primary storage device of the management terminal apparatus 30. The RAM 132 temporarily stores at least part of programs to be executed by the CPU 131. Also, the RAM 132 stores various kinds of data used for processing by the CPU 131.

The peripheral devices connected to the bus 138 include a HDD 133, a graphics processing device 134, an input interface 135, a drive device 136, and a communication interface 137.

The HDD 133 is used as the secondary storage device of the management terminal apparatus 30. Programs to be executed by the CPU 131, and various kinds of data are stored in the HDD 133. As the secondary storage device, a semiconductor storage device such as a flash memory may be used as well.

The graphics processing device 134 is connected with a monitor 134 a. The graphics processing device 134 causes an image to be displayed on the screen of the monitor 134 a, in accordance with an instruction from the CPU 131. Examples of the monitor 134 a include a display device using a Cathode Ray Tube (CRT), and a liquid crystal display device.

The input interface 135 is connected with, for example, a keyboard 135 a and a mouse 135 b. The input interface 135 transmits a signal sent from the keyboard 135 a or the mouse 135 b to the CPU 131. The mouse 135 b is an example of pointing device, and another pointing device may be used as well. Examples of another pointing device include a touch panel, a tablet, a touch pad, and a track ball.

The drive device 136 reads data recorded on an optical disc 136 a by using laser light or the like. The optical disc 136 a is a portable recording medium on which data is stored in a manner that allows the data to be read by reflection of light. Examples of the optical disc 106 a include a Digital Versatile Disc (DVD), a DVD-ROM, a Compact Disc Read Only Memory (CD-ROM), and a CD-Recordable (R)/ReWritable (RW).

The communication interface 137 transmits and receives data to and from the controller module 10 a, 10 b via a LAN cable.

The host apparatus 20 may be implemented in the same hardware configuration as that in FIG. 4. However, a communication interface included in the host apparatus 20 transmits and receives data to and from the controller module 10 a, 10 b via an optical fiber.

FIG. 5 is a block diagram illustrating an example of processing functions included in the controller modules 10 a and 10 b.

Basically, processing functions included in the controller module 10 a are described with reference to FIG. 5, and a description of processing functions included in the controller module 10 b is omitted.

The CPU 11 a has an IO access control unit 111 a. The IO access control unit 111 a controls access to a HDD in the DE 210, 220. The IO access control unit 111 a receives an access request for a HDD in the DE 210 or a HDD in the DE 220, which is issued from the host apparatus 20, from the CA 14 a or the CA 15 a. Then, the IO access control unit 111 a accesses the HDD in the DE 210 or the HDD in the DE 220 via a straight path or a cross path.

When making access to the DE 210, 220, the IO access control unit 111 a designates which one of a straight path and a cross path is to be used by the IOC 16 a, 17 a to access the DE 210, 220. When making access to the DE 210, 220, the IO access control unit 111 a determines which one of a straight path and a cross path is to be used to access the DE 210, 220, on the basis of expander (EXP) state information 161 a and other-expander state information 162 a stored in the RAM 12 a.

The expander state information 161 a is information indicating the operating state of the expander 18 a, 19 a of the controller module 10 a. The other-expander state information 162 a is information indicating the operating state of the expander 18 b, 19 b of the other controller module 10 b. Specifically, the expander state information 161 a and the other-expander state information 162 a both take the two kinds of values “Normal” indicating that the corresponding expander is available for use, and “Fault” indicating that the corresponding expander is not available for use.

The IO access control unit 111 a accesses the DE 210, 220 by using a path that goes through an expander corresponding to the state information whose value is “Normal” out of the expander state information 161 a and the other-expander state information 162 a. For example, if the expander state information 161 a and the other-expander state information 162 a are both “Normal”, the IO access control unit 111 a accesses the DE 210, 220 by using a straight path. If the expander state information 161 a is “Normal”, and the other-expander state information 162 a is “Fault”, the IO access control unit 111 a accesses the DE 210, 220 by using a straight path. If the other-expander state information 162 a is “Normal”, and the expander state information 161 a is “Fault”, the IO access control unit 111 a accesses the DE 210, 220 by using a cross path.

Next, the functions of the expanders 18 a, 19 a, 18 b, and 19 b are described. While the function of the expander 18 a is described hereinafter, the expanders 19 a, 18 b, and 19 b also have the same functions as the expander 18 a.

FIG. 6 is a block diagram illustrating the functions of the expanders 18 a and 19 a.

The expander 18 a has an EXP determination unit 181 a, a state monitoring unit 182 a, a control-power control unit 183 a, an other-system DE connection request unit 183 a, an own-system DE connection request unit 184 a, and an EXP-DE connection unit 186 a.

The EXP determination unit 181 a accesses the NVRAM 24 a via the FPGA 23 a to determine that the expander of the own system is the expander 18 a.

Upon supply of power to the expander 18 a from the PSU 40 a or the PSU 40 b, the state monitoring unit 182 a operated by a resident power source starts monitoring of the state of hardware in the controller module 10 a when instructed from the user, for example. The items to be monitored include, for example, the temperature detected by a temperature sensor placed at a predetermined location in the controller module 10 a, the voltage detected by a voltage sensor placed at a predetermined location in the controller module 10 a, and component mounting status. These pieces of information are stored in, for example, the NVRAM 24 a. The state monitoring unit 182 a performs monitoring by periodically reading information stored in the NVRAM 24 a. While temperature, voltage, and component mounting status are given as an example of monitoring items in this embodiment, the monitoring items are not limited to temperature, voltage, and component mounting status. At the point when monitoring of the state of hardware in the controller module 10 a is started, power is supplied only to the expander 18 a and the expander 19 a, and power is not supplied to the main control unit 110 a.

The state monitoring unit 182 a causes the controller module 10 a to transition to a first power-on state or a second power-on state described later, in accordance with the presence/absence of a fault determined as a result of monitoring (if a fault is present, the kind of the fault). When effecting a transition to the first power-on state or the second power-on state, the state monitoring unit 182 a requests the control-power control unit 183 a, the other-system DE connection request unit 184 a, the own-system DE connection request unit 185 a, and the EXP-DE connection unit 185 a to perform processing described later.

The control-power control unit 183 a supplies the power supplied from the PSU 40 a or the PSU 40 b, to the main control unit 110 a upon request from the state monitoring unit 182 a. When power is supplied to the main control unit 110 a, the IO access control unit 111 a establishes connection with the expander 18 a, 19 a and the expander 18 b, 19 b.

The other-system DE connection request unit 184 a requests the expander 18 b to establish connection of the expander 18 b to the DE 210, 220, upon request from the state monitoring unit 182 a.

The own-system DE connection request unit 185 a requests the expander 19 a to establish connection of the expander 19 a to the DE 210, 220, upon request from the state monitoring unit 182 a.

The EXP-DE connection unit 186 a supplies the power supplied from the PSU 40 a or the PSU 40 b, to the DE 210, 220 upon request from the state monitoring unit 182 a. Also, the EXP-DE connection unit 186 a establishes connection between the expander 18 a and the DE 210, 220.

The expander 19 a has an EXP determination unit 191 a, and an EXP-DE connection unit 192 a. The EXP determination unit 191 a has the same function as that of the EXP determination section 181 a. The EXP-DE connection unit 192 a supplies the power supplied from the PSU 40 a or the PSU 40 b, to the DE 210, 220 upon request for establishing connection with the DE 210, 220 made from the own-system DE connection request unit 185 a. Also, the EXP-DE connection unit 192 a establishes connection between the expander 19 a and the DE 210, 220.

Next, the first power-on state and the second power-on state that may be assumed by the controller module 10 a are described.

When the state monitoring unit 182 a determines that a fault has not occurred as a result of monitoring the above-mentioned monitoring items, the state monitoring unit 182 a notifies the control-power control unit 183 a, the other-system DE connection request unit 184 a, the own-system DE connection request unit 185 a, and the EXP-DE connection unit 186 a of a first request for causing the power-on state of the controller 10 a to transition to the first power-on state. Upon receiving the first request, the control-power control unit 183 a supplies the power supplied from the PSU 40 a or the PSU 40 b, to the main control unit 110 a. When power is supplied to the main control unit 110 a, the IO access control unit 111 a establishes connection with the expander 18 a, 19 a and the expander 18 b, 19 b. Upon receiving the first request, the other-system DE connection request unit 184 a requests the expander 18 b to establish connection with the DE 210, 220. The expander 18 b may ignore the request from the other-system DE connection request unit 184 a if connection with the DE 210, 220 has already been established. Upon receiving the first request, the own-system DE connection request unit 185 a requests the expander 19 a to establish connection with the DE 210, 220. Upon receiving the first request, the EXP-DE connection unit 186 a supplies the power supplied from the PSU 40 a or the PSU 40 b, to the DE 210, 220. Also, the EXP-DE connection unit 186 a establishes connection between the expander 18 a and the DE 210, 220. Therefore, it becomes possible to access the DE 210, 220 from the host apparatus 20 via the controller module 10 a. Moreover, it also becomes possible for the controller module 10 b to access the DE 210, 220 via a cross path (that is, an access path that goes through the expander 18 a, 19 a of the controller module 10 a).

On the other hand, if, as a result of monitoring the above-mentioned monitoring items, the state monitoring unit 182 a determines that a fault has occurred but this fault is not related to temperature or voltage, the state monitoring unit 182 a determines the fault to be a relatively minor fault, and continues the state monitoring as it is. The criterion for determining whether a fault is minor is not limited to the one described in this embodiment. Then, if the state monitoring unit 182 a receives a connection establishment request from the expander 18 b while continuing the state monitoring, the state monitoring unit 182 a notifies the own-system DE connection request unit 185 a and the EXP-DE connection unit 186 a of a second request for causing the power-on state of the controller module 10 a to transition to the second power-on state. Upon receiving the second request, the own-system DE connection request unit 185 a requests the expander 19 a to establish connection with the DE 210, 220. Upon receiving the second request, the EXP-DE connection unit 186 a supplies the power supplied from the PSU 40 a or the PSU 40 b, to the DE 210, 220. Also, the EXP-DE connection unit 186 a establishes connection between the expander 18 a and the DE 210, 220. In the second power-on state, power is not supplied to the main control unit 110 a, and thus it is not possible to access the DE 210, 220 from the host apparatus 20 via the controller module 10 a. However, the transition to the second power-on state causes the expander 18 a, 19 a to become operational. Therefore, in a state in which a main control unit 110 b of the controller module 10 b is activated, it is possible for the host apparatus 20 to access the DE 210, 220 by using a cross path that goes through the expander 18 a, 19 a. In the second power-on state, it is possible for the controller module 10 b to access the DE 210, 220 by selectively using two paths, a straight path and a cross path. This maintains a state in which redundancy is provided for the access path from the controller module 10 b to the DE 210, 220. Also, in the second power-on state, when the state monitoring unit 182 a determines as a result of monitoring that the fault has been resolved, the state monitoring unit 182 a notifies the control-power control unit 183 a, the other-system DE connection request unit 184 a, the own-system DE connection request unit 185 a, and the EXP-DE connection unit 186 a of the first request for causing the power-on state of the controller 10 a to transition to the first power-on state. When the first request is received after the second request, the own-system DE connection request unit 185 a and the EXP-DE connection unit 186 a may ignore the first request because of overlapping processing.

If, as a result of determining the kind of the fault, the state monitoring unit 182 a determines the fault that has occurred to be related to temperature or voltage, the state monitoring unit 182 a determines the fault to be a relatively major fault, and turns off the power to the expander 18 a. The criterion for determining whether a fault is major is not limited to the one described in this embodiment.

Like the controller module 10 a, the controller module 10 b also assumes at least two kinds of states, the first power-on state and the second power-on state, as its power-on state.

While this embodiment is directed to the case where the expander 19 a has a function different from the function of the expander 18 a, the expander 19 a may have a function equivalent to the function of the expander 18 a.

Next, a description is given of processing in the expander 18 a and the expander 19 a when the PSU 40 a or the PSU 40 b supplies power to the expander 18 a in a state in which power is not being supplied to the controller module 10 a.

FIG. 7 is a method illustrating processing in the expanders 18 a and 19 a. In FIG. 7, for the convenience of description, the expander 18 a is noted as “own-system first expander”, the expander 19 a is noted as “own-system second expander”, and the expander 18 b is noted as “own-system first expander”.

In step S1, the EXP determination unit 181 a and the EXP determination unit 191 a each determine whether the expander of the own system is the expander 18 a or the expander 19 a. If the own system's expander is the expander 18 a (step S1; Yes), the processing shifts to step S2. If the own system's expander is the expander 19 a (step S1; No), the processing shifts to step S12.

In step S2, the state monitoring unit 182 a starts state monitoring. Then, the state monitoring unit 182 a determines whether or not a connection establishment request has been accepted from the expander 18 b. If a connection establishment request has been accepted from the expander 18 b (step S2; Yes), the processing shifts to step S3. If a connection establishment request has been accepted from the expander 18 b (step S2: No), the processing shifts to step S5.

In step S3, the state monitoring unit 182 a notifies the own-system DE connection request unit 185 a and the EXP-DE connection unit 186 a of the second request for effecting a transition to the second power-on state. Upon receiving the second request, the EXP-DE connection unit 186 a establishes connection between the expander 18 a and the DE 210, 220. Thereafter, the processing shifts to step S4.

In step S4, upon receiving the second request, the own-system DE connection request unit 185 a requests the expander 19 a to establish connection with the DE 210, 220. Thereafter, the processing shifts to step S5.

In step S5, the state monitoring unit 182 a determines whether or not a fault has occurred in the controller module 10 a. If it is determined that a fault has occurred in the controller module 10 a (step S5; Yes), the processing shifts to step S6. If it is determined that a fault has not occurred in the controller module 10 a (step S5; No), the processing shifts to step S8.

In step S6, the state monitoring unit 182 a determines whether or not the fault that has occurred is related to temperature or voltage. If it is determined that the fault that has occurred is related to temperature or voltage (step S6; Yes), the processing shifts to step S7. If it is determined that the fault that has occurred is not related to temperature or voltage (step S6; No), the processing shifts to step S2.

In step S7, the state monitoring unit 182 a turns off the power to the expander 18 a. Thereafter, the processing in FIG. 7 is ended.

In step S8, hereinafter, in steps S8 and steps S9 to S11, a process of effecting a transition to the first power-on state is executed. First, the state monitoring unit 182 a notifies the EXP-DE connection unit 186 a of the first request. Thereafter, the processing shifts to step S9. Upon receiving the first request, the EXP-DE connection unit 186 a supplies the power supplied from the PSU 40 a or the PSU 40 b, to the DE 210, 220. Also, the EXP-DE connection unit 186 a establishes connection between the expander 18 a and the DE 210, 220.

In step S9, the state monitoring unit 182 a notifies the other-system DE connection request unit 184 a of the first request. Thereafter, the processing shifts to step S10. Upon receiving the first request, the other-system DE connection request unit 184 a requests the expander 18 b to establish connection with the DE 210, 220. As mentioned previously, if connection with the DE 210, 220 has already been established, the expander 18 b may ignore the request from the other-system DE connection request unit 184 a.

In step S10, the state monitoring unit 182 a notifies the own-system DE connection request unit 185 a of the first request. Thereafter, the processing shifts to step S11. Upon receiving the first request, the own-system DE connection request unit 185 a requests the expander 19 a to establish connection with the DE 210, 220. Upon request for establishing connection with the DE 210, 220 from the own-system DE connection request unit 185 a, the EXP-DE connection unit 192 a supplies the power supplied from the PSU 40 a or the PSU 40 b, to the DE 210, 220. Also, the EXP-DE connection unit 192 a establishes connection between the expander 19 a and the DE 210, 220.

In step S11, the state monitoring unit 182 a notifies the control-power control unit 183 a of the first request. Thereafter, the processing in FIG. 7 is ended. Upon receiving the first request, the control-power control unit 183 a supplies the power supplied from the PSU 40 a or the PSU 40 b, to the main control unit 110 a. With the supply of power to the main control unit 110 a, the main control unit 110 a is activated, and establishes connection with the expander 18 a, 19 a.

In step S12, the EXP-DE connection unit 192 a determines whether or not a request for establishing connection between the expander 19 a and the DE 210, 220 has been accepted from the expander 18 a. If a request for establishing connection between the expander 19 a and the DE 210, 220 has been accepted from the expander 18 a (step S12; Yes), the processing shifts to step S13. If a request for establishing connection between the expander 19 a and the DE 210, 220 has not been accepted from the expander 18 a (step S12; No), the EXP-DE connection unit 192 a waits for acceptance of a request for establishing connection between the expander 19 a and the DE 210, 220.

In step S13, the EXP-DE connection unit 192 a supplies the power supplied from the PSU 40 a or the PSU 40 b, to the DE 210, 220. Also, the EXP-DE connection unit 192 a establishes connection between the expander 19 a and the DE 210, 220. Thereafter, the processing in FIG. 7 is ended.

As has been described above, according to the storage apparatus 100, a redundant path between the host apparatus 20 and the DE 210, 220 may be secured if either one of the main control units 110 a and 110 b is activated. Accordingly, the safety of device operation may be ensured.

While the storage apparatus and the control method for the storage apparatus according to the embodiments have been described above with reference to the drawings, the embodiments are not limited to these embodiments. The configuration of each individual unit may be substituted by another arbitrary configuration that provides the same function. Also, other arbitrary structures or steps may be added to the embodiments.

Of the aforementioned embodiments, arbitrary two or more configurations (features) may be used in combination.

The above-mentioned processing functions may be implemented by a computer. In that case, a program describing the details of processing executed by functions included in the first controller 4, the second controller 5, and the controller module 10 a, 10 b is provided. By executing the program by a computer, the above-mentioned processing functions are implemented on the computer. The program describing the details of processing may be pre-recorded on a computer-readable recording medium. Examples of the computer-readable recording medium include a magnetic storage device, an optical disc, a magneto-optical recording medium, and a semiconductor memory. Examples of the magnetic storage device include a hard disk drive, a flexible disc (FD), and a magnetic tape. Examples of the optical disc include a DVD, a DVD-RAM, and a CD-ROM/RW. Examples of the magneto-optical recording medium include a Magneto-Optical disk (MO).

To distribute a program, for example, a portable recording medium such as a DVD or a CD-ROM on which the program is recorded is sold. Also, the program may be stored in a storage device of a server computer in advance, and the program may be transferred to another computer from the server computer via a network.

A computer that executes a program stores a program recorded on a portable recording medium or a program transferred from a server computer, into its own storage device. Then, the computer reads the program from its own storage device, and executes processing according to the program. The computer may be also configured to read a program directly from a portable recording medium, and execute processing according to the program. Also, the computer may be configured to execute processing according to a received program sequentially every time a program is transferred from a server computer connected via a network.

At least part of the above-mentioned processing functions may be also implemented by an electronic circuit such as a Digital Signal Processor (DSP), an Application Specific Integrated Circuit (ASIC), or a Programmable Logic Device (PLD).

All examples and conditional language recited herein are intended for pedagogical purposes to aid the reader in understanding the invention and the concepts contributed by the inventor to furthering the art, and are to be construed as being without limitation to such specifically recited examples and conditions, nor does the organization of such examples in the specification relate to a showing of the superiority and inferiority of the invention. Although the embodiments of the present invention have been described in detail, it should be understood that the various changes, substitutions, and alterations could be made hereto without departing from the spirit and scope of the invention. 

1. A storage apparatus comprising: a first controller that generates an access to a storage device; the first controller includes: a first relay unit configured to relay the access to the storage device; and an access control unit configured to be activated after activation of the first relay unit and to relay the access to the storage device via a second relay unit; and a second controller that includes the second relay unit and generates the access to the storage device, wherein when the first relay unit receives a connection request for an access path between the first relay unit and the storage device from the second controller, the first relay unit establishes the access path to the storage device irrespective of an activation state of the access control unit.
 2. The storage apparatus according to claim 1, wherein after establishing the access path to the storage device, the first relay unit notifies the second relay unit of a connection request to the storage device, and upon receiving the connection request, the second relay unit establishes an access path to the storage device irrespective of an activation state of the access control unit of the second controller.
 3. The storage apparatus according to claim 2, wherein when the second relay unit receives the connection request for connection between the second relay unit and the storage device in a state in which the access path to the storage device is established, the second relay unit ignores the connection request.
 4. The storage apparatus according to claim 1, further comprising: a sensor configured to detect occurrence of a fault in the first controller, wherein when the sensor detects the occurrence of the fault, depending on a kind of the fault, the access control unit does not activate itself, and the first relay unit maintains a state in which the access path to the storage device is established.
 5. A controlling method performed by a storage apparatus that includes a first controller and a second controller each generating an access to a storage device, the controlling method comprising: relaying the access to the storage device by a first relay unit included in the first controller; and establishing an access path to the storage device by the first relay unit, irrespective of an activation state of an access control unit, when the first relay unit receives a connection request for the access path between the first relay unit and the storage device from the second controller before the access control unit in the first controller is activated to control the access to the storage device via a second relay unit included in the second controller. 